RU2002126258A - AN IMPLANT BASED ON A MULTIPHASIC MICROPHOTODETECTOR FOR AN EYE NET WITH A VARIABLE VOLTAGE AND CURRENT AND A DEVICE FOR ITS INSERT - Google Patents

Abstract

A visible and infrared light powered retinal implant is disclosed that is implanted into the subretinal space for electrically inducing formed vision in the eye. The retinal implant includes a stacked microphotodetector arrangement having an image sensing pixel layer and a voltage and current gain adjustment layer for providing variable voltage and current gain to the implant so as to obtain better low light implant performance than the prior art, and to compensate for high retinal stimulation thresholds present in some retinal diseases. A first light filter is positioned on one of the microphotodetectors in each of the image sensing pixels of the implant, and a second light filter is positioned on the other of the microphotodetectors in the image sensing pixel of the implant, each of the microphotodetectors of the pixel to respond to a different wavelength of light to produce a sensation of darkness utilizing the first wavelength, and a sensation of light using the second wavelength, and a third light filter is positioned on a portion of the voltage and current gain adjustment layer that is exposed to light, to allow adjustment of the implant voltage and current gain of the device by use of a third wavelength of light.

Claims (29)

1. A retinal implant for electrically inducing a shaped image in the eye, comprising a plurality of pairs of microphotostacks of the first layer to receive light incident on the eye, wherein each pair of microphotostacks of the first layer contains a PiN microphotograph and a NiP microphotograph, the P-part of the PiN microphotograph and the N-part the NiP microphotographs are aligned at the first end, while the N-part of the PiN microphotographs and the P-part of the NiP microphotographs are aligned at the second end, and a common electrode electrically connected between a part and an N-part of a first end of a pair of microphotostacks, a gain adjustment layer having a first side and a second side, wherein the first side comprises a first part electrically connected in series with a second end of at least a portion of a plurality of pairs of microphotostacks of the first layer, and the second part, formed at the same time with the first part and extending from the first part, the second part is oriented to receive light incident on the eye, and the common electrode plane located in electrical inter Procedure with the second side of the gain adjustment layer, whereby the common electrode plane serves as an electrical ground for the retinal implant. 2. The retinal implant according to claim 1, characterized in that the gain adjustment layer comprises at least one PiN photodetector having a P-part and an N-part, while the P-part of at least one PiN layer photodetector the gain adjustment is in electrical interaction with the N-part of at least one of the PiN microphotostacks pairs of microphotosts of the first layer. 3. The retinal implant according to claim 1, characterized in that the gain control layer comprises at least one NiP photodetector having an N-part and a P-part, wherein the N-part of at least one NiP photodetector is in electrical interaction with the P-part of at least one of the NiP microphotoelectric receivers of the microphotoelectric couple of the first layer. 4. The retinal implant according to claim 1, characterized in that the gain control layer comprises a plurality of parallel planks of PiN and NiP photodetectors. 5. The retinal implant according to claim 4, characterized in that the plurality of pairs of micro-photodetectors of the first layer contain columns of pairs of micro-photodetectors, the N-part of the PiN micro-detector in pair being in electrical interaction with the P-part of the plate of the PiN photodetector in the gain layer, and P- a portion of the NiP microphotograph in a pair is in electrical interaction with the N-part of the strip of the NiP detector in the gain layer. 6. The retinal implant according to claim 4, characterized in that the plurality of parallel bars of the PiN and NiP photodetectors are arranged in an alternating configuration. 7. The retinal implant according to claim 1, characterized in that the first end of the second part of the gain adjustment layer is coated with a first filter material, the configuration of which passes the first pre-set part of the wavelengths of visible and infrared radiation, selected from a range of 400 nm to 2 μm. 8. The retinal implant according to claim 7, characterized in that the first predetermined part of the wavelengths of visible and infrared radiation is selected from a range from 800 nm to 2 μm. 9. The retinal implant according to claim 7, characterized in that each of said plurality of pairs of microdetectors of the first layer comprises a second filter material located above the N-part at the first end of at least one of said plurality of pairs of microdetectors. 10. The retinal implant according to claim 9, characterized in that the configuration of the second filter material passes a second predetermined part of the wavelengths of visible and infrared radiation in the range from 400 nm to 2 μm. 11. The retinal implant of claim 10, wherein the second predetermined portion of the wavelengths is different from the first predetermined portion of the wavelengths. 12. The retinal implant according to claim 11, characterized in that the second predetermined part of the wavelengths is selected from the range from 650 to 800 nm. 13. The retinal implant according to any one of claims 7 to 11, characterized in that the plurality of pairs of microreceptors of the first layer contain a third filter material located above the P-part at the first end of at least one of the plurality of pairs of microreceptors. 14. The retinal implant according to item 13, wherein the configuration of the third filter material passes a third predetermined part of the wavelengths in the range from 400 nm to 2 μm. 15. The retinal implant of claim 14, wherein the third predetermined portion of the wavelengths is different from the first and second predetermined portion of the wavelengths. 16. The retinal implant according to clause 15, wherein the third predetermined part of the wavelengths is selected from the range from 400 to 650 nm. 17. A retinal implant for electrically inducing a shaped image in the eye, comprising a plurality of microphotomotive image elements, each of the plurality of microphotomotive image elements being distant from any adjacent microphotomotive image elements, and each of the image elements is inserted into a grating, each microphotomotive image element contains, at least a pair of micro-photodetectors of the first layer for receiving light incident on the eye, with each pair The microphotograph contains a PiN microphotograph and a NiP microphotograph, with the P-part of the PiN microphotograph and the N-part of the NiP microphotograph aligned at the first end, while the N-part of the PiN microphotograph and the P-part of the NiP microphotograph are aligned at the second end, and a common electrode electrically connected between The P-part and the N-part of the first end of the pair of microphotographs, a gain control layer having a first side and a second side, the first side comprising a first part electrically connected to a follower but the second end of the at least a portion of the plurality of pairs mikrofotopriemnikov first layer and a second portion formed integrally with the first portion and extending from the first portion, the second portion is oriented to receive light incident on the eye. 18. The retinal implant according to claim 17, characterized in that the lattice mesh comprises a common ground electrode electrically connected to the whole set of image elements of the microphotostacks. 19. A method of adjusting the voltage and current gain in an implant located in the retina of the eye, in which a retinal implant is provided having a light-sensitive photosensitive layer and a light-fed voltage and current gain adjustment layer, the light-fed coefficient adjustment layer the voltage and current amplification has a band-pass filter for transmitting the first predetermined part of the wavelength of the incident visible and infrared radiation, and the retinal implant is located in eye, receive a light source in a predetermined part of the wavelength, and illuminate at least part of the retinal implant with a light source to adjust the image gain of visible radiation and / or infrared radiation incident on the eye. 20. A retinal implant injector for placing a retinal implant in the eye, wherein the retinal implant comprises an elongated hollow tube having a first open end, a second open end and a housing extending between the first and second open ends, the first end contains a tapered, conical hole, and a second the end contains a circular hole having a diameter that is less than the width of the housing extending between the first and second open ends. 21. The injector device of the retinal implant according to claim 19, characterized in that said device is made of Teflon (polytetrafluoroethylene). 22. A retinal injector kit comprising a retinal implant injector for placing a retinal implant in the eye, wherein the retinal implant injector comprises an elongated hollow tube having a first open end, a second open end and a housing extending between the first and second open ends, the first end comprising a tapered , a conical hole, and the second end contains a circular hole having a diameter that is smaller than the width of the housing extending between the first and second open ends, the first end of the channel It is inserted into the second end of the retinal implant injector, and a syringe, wherein the round end of the retinal implant injector device is inserted around the cannula tip and a cannula attached to a syringe, which is filled with a liquid for injection. 23. The retinal injector kit according to claim 22, wherein the injection liquid is a biocompatible liquid. 24. The retinal injector kit according to claim 22, wherein the injection liquid is a saline-based liquid. 25. The retinal injector kit according to claim 22, wherein the injection liquid is viscoelastic. 26. A retinal implant based on microphotographs with adjustable voltage and current gain for electrically inducing a formed image in the eye, comprising a first microphotomaker layer comprising at least one PiN microphotomotive receiver, the first microphotomotive layer having a bandpass filter, the configuration of which passes visible radiation, and a voltage and current gain adjustment layer comprising at least one PiN photodetector, coefficient adjustment layer a voltage and current amplification unit having a first side comprising a first part electrically connected in series with and coated with a portion of at least one PiN microphotomotive receiver of a first microphotomotive layer and a second portion not covered by a first microphotomotive receiver layer containing an infrared bandpass filter . 27. The retinal implant according to p. 26, containing at least one upper electrode located on the first layer of microphotographs, and at least one lower electrode located on the layer of gain adjustment for voltage and current, while the upper and the lower electrodes contain atomized iridium / iridium oxide. 28. A retinal implant for electrically inducing a shaped image in the eye, comprising a first layer having a plurality of micro-photodetector pairs, each pair of micro-photodetectors comprising a PiN micro-photodetector and a NiP micro-photodetector, wherein the P part of the PiN micro photo detector and the N part of the NiP micro photo detector are aligned at the first end, whereas the N-part of the PiN microphotograph and the P part of the NiP microphotograph are aligned at the second end, and the common electrode electrically connected between the P part and the N part of the first end of the mic pair pickups, the first common electrode strip in electrical interaction with the N-parts of the second end of each of the number of multiple PiN microphotographs of pairs of microphotographs, the second common electrode strip in electrical interaction with the P-parts of the second end of each of the number of multiple NiP microphotographs of pairs of microphotographs PiN / NiP, gain layer of the photodetector gain of the second layer, containing the first end of the first part, electrically connected in series with common electrode strips, as an N-hour and both of the P-part of the second end of the first layer of pairs of microphotostacks, and the second part, made at the same time as the first part, extending beyond the first part and oriented towards the reception of light incident on the eye, and the common electrode plane for the voltage gain adjustment layer and the current of the second layer in direct electrical connection with the second end of both the first part and the second part of the voltage and current gain adjustment layer, the common electrode plane serving as the electric ground for a retinal implant. 29. A retinal injector kit comprising a retinal implant injector for placing a retinal implant in the eye, wherein the retinal implant injector comprises an elongated hollow tube having a first open end, a second open end and a body extending between the first and second open ends, and an injector rod, located inside the case, whose position is regulated by the operator, the first end contains a tapered, conical hole; and the second end comprise a circular hole having a diameter that is smaller than the width of the body extending between the first and second open ends, a syringe connected to the injector for regulating the movement of the injector rod by means of an extension located between the injector rod and the syringe rod.